Tolerance to biodegraded crude oil in marine invertebrate embryos and larvae is associated with expression of a multixenobiotic resistance transporter.

The toxicity of water-soluble fractions of biodegraded crude oil (BWSF) to embryos and larvae of two marine invertebrates, the white sea urchin (Lytechinus anamesus) and the fat innkeeper (Urechis caupo), was studied. Santa Barbara Channel crude oil was artificially weathered and subjected to biodegradation using a mixed microbe culture obtained from natural oil seep sites. The degradation culture inoculated with seep sediment microbes accumulated 43.7 microg/l water-soluble hydrocarbons. In contrast water-soluble fractions from the non-degraded cultures (NWSF) only accumulated 3.05 microg/l. BWSF proved deleterious to Lytechinus embryo development at low concentrations (EC50 = 0.33 mg/l) but was essentially non-toxic to Urechis embryos/larvae up to 3.0 mg/l. An established mechanism for handling of a wide array of xenobiotics in Urechis embryos is the multixenobiotoic resistance transporter multixenobiotic response (MXR, also known as multidrug resistance, MDR). This mechanism is primarily mediated by ATP-dependent, efflux pumps that extrude a wide array of xenobiotic compounds. In this study, we show that Lytechinus larvae do not appear to express MXR efflux protein nor MXR mediated dye efflux capacity. In contrast, BWSF acts as a competitive inhibitor of MXR transport-mediated dye efflux in Urechis larvae. These results suggest that MXR may be an important mechanism for extrusion of the by-products of crude oil degradation by microbes, and that the level of its expression may determine the susceptibility of organisms to degraded oil hydrocarbons.

Sperm of the Shrimp Sicyonia ingentis Undergo a Bi-Phasic Capacitation Accompanied by Morphological Changes.

Sperm removed from seminal receptacles of female Sicyonia ingentis can be induced to undergo a bi-phasic acrosome reaction (AR), acrosomal exocytosis followed by filament formation, using egg water (EW). Sperm removed from males will not undergo any phase of the AR when incubated with EW, indicating that these sperm undergo a capacitation process after insemination. Freshly molted females (functional virgins) were placed in aquaria with males and monitored for copulation. Mated females were isolated and allowed to carry sperm for specific periods of time. At these time points, sperm were removed and assayed for the ability to undergo the AR using EW. The results indicate that sperm are competent to undergo acrosomal exocytosis after approximately 25 hr, while competency to form acrosomal filaments is not achieved until around 145 hr post-insemination. Morphological examination of sperm removed from males and sperm removed from females revealed dramatic differences. Microscopic evidence indicates that some of the morphological changes seen during capacitation are necessary for the successful completion of the AR.